Wave-front phase estimation from Fourier intensity measurements

Cederquist, Jack N.; Fienup, James R.; Wackerman, C.; Robinson, Stanley R.; Kryskowski, David

doi:10.1364/josaa.6.001020

Cited by 53 publications

(27 citation statements)

References 9 publications

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“…It should be noted, however, that occurrences of inconsistent set-theoretic formulations in phase retrieval or other signal recovery problems are far from being academic, as a result of noisy data, measurement errors, or inaccurate a priori information. 21,[46][47][48][49] Several investigations have been devoted to analyzing and coping with this situation in convex problems. [50][51][52][53][54][55] While the infinite-dimensional space L appears to be the most appropriate signal space to model the physics of the problem and to describe the subtle properties of the algorithms in their full generality, we shall also call attention to finite-dimensional versions of the results whenever these happen to differ from their infinitedimensional counterparts.…”

Section: Phase Retrieval and Feasibilitymentioning

confidence: 99%

Phase retrieval, error reduction algorithm, and Fienup variants: a view from convex optimization

2002

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The phase retrieval problem is of paramount importance in various areas of applied physics and engineering. The state of the art for solving this problem in two dimensions relies heavily on the pioneering work of Gerchberg, Saxton, and Fienup. Despite the widespread use of the algorithms proposed by these three researchers, current mathematical theory cannot explain their remarkable success. Nevertheless, great insight can be gained into the behavior, the shortcomings, and the performance of these algorithms from their possible counterparts in convex optimization theory. An important step in this direction was made two decades ago when the error reduction algorithm was identified as a nonconvex alternating projection algorithm. Our purpose is to formulate the phase retrieval problem with mathematical care and to establish new connections between well-established numerical phase retrieval schemes and classical convex optimization methods. Specifically, it is shown that Fienup's basic input-output algorithm corresponds to Dykstra's algorithm and that Fienup's hybrid input-output algorithm can be viewed as an instance of the Douglas-Rachford algorithm. We provide a theoretical framework to better understand and, potentially, to improve existing phase recovery algorithms.

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Section: Phase Retrieval and Feasibilitymentioning

confidence: 99%

Phase retrieval, error reduction algorithm, and Fienup variants: a view from convex optimization

2002

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“…However, if DHM is used to study microscopic samples of large BW, the isolation of the object field component, in the hologram, cannot be realized by this simple spatial filtering procedure. In this case, one of the useful procedures is to perform the elimination of non desired hologram components by iterative procedures (Fienup, 1987;Cederquist et al, 1989;Wu, 2004;Denis et al, 2005;Hwang-Han, 2007;Nakamura, 2007). In this chapter we describe an iterative method that effectively recovers the object field component from the recorded hologram, in both the LOADH and RLOADH setups.…”

Section: Introductionmentioning

confidence: 99%

Iterative Noise Reduction in Digital Holographic Microscopy

Arrizón¹,

Ruiz²,

Cruz³

2011

Holography, Research and Technologies

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“…A phaseretrieval algorithm iteratively searches for a phase estimate that defines an optical field that, when digitally propagated to the measurement planes, has intensity distributions in agreement with the measured intensities. The method has been successfully employed in the past for image recovery [1][2][3], wavefront sensing for adaptive optics [4], and for diagnosing the aberrations of the Hubble Space Telescope [5,6]. It will be used to align the segments of the James Webb Space Telescope [7].…”

Section: Introductionmentioning

confidence: 99%

Measurement range of phase retrieval in optical surface and wavefront metrology

Brady

Fienup

2009

Appl. Opt.

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Phase retrieval employs very simple data collection hardware and iterative algorithms to determine the phase of an optical field. We have derived limitations on phase retrieval, as applied to optical surface and wavefront metrology, in terms of the speed of beam (i.e., f -number or numerical aperture) and amount of aberration using arguments based on sampling theory and geometrical optics. These limitations suggest methodologies for expanding these ranges by increasing the complexity of the measurement arrangement, the phase-retrieval algorithm, or both. We have simulated one of these methods where a surface is measured at unusual conjugates.

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Wave-front phase estimation from Fourier intensity measurements

Cited by 53 publications

References 9 publications

Phase retrieval, error reduction algorithm, and Fienup variants: a view from convex optimization

Phase retrieval, error reduction algorithm, and Fienup variants: a view from convex optimization

Iterative Noise Reduction in Digital Holographic Microscopy

Measurement range of phase retrieval in optical surface and wavefront metrology

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